Methods And Systems For Determining That A Video-Capturing Device Is Unsteady

ABSTRACT

In one aspect, an example method includes (i) capturing, by a computing system, via a camera of the computing system, video content; (ii) encoding, by the computing system, the captured video content to generate a video stream; and (iii) while generating the video stream: (a) making, by the computing system, a determination that each condition in a condition set is satisfied, wherein the condition set includes a condition relating to a change in a data rate of the video stream; and (b) responsive to making the determination, outputting, by the computing system, via a user interface of the computing system, an indication that the computing system is unsteady.

RELATED DISCLOSURES

This disclosure is a continuation of U.S. patent application Ser. No.15/295,767 filed on Oct. 17, 2016, which claims priority to U.S.Provisional Patent Application No. 62/242,593, titled “Video ProductionSystem with Content-Related Features,” filed on Oct. 16, 2015, which arehereby incorporated by reference in their entirety.

USAGE AND TERMINOLOGY

In this disclosure, unless otherwise specified and/or unless theparticular context clearly dictates otherwise, the terms “a” or “an”mean at least one, and the term “the” means the at least one.

SUMMARY

In one aspect, an example method is disclosed. The method includes (i)capturing, by a computing system, via a camera of the computing system,video content; (ii) encoding, by the computing system, the capturedvideo content to generate a video stream; and (iii) while generating thevideo stream: (a) making, by the computing system, a determination thateach condition in a condition set is satisfied, wherein the conditionset includes a condition relating to a change in a data rate of thevideo stream; and (b) responsive to making the determination,outputting, by the computing system, via a user interface of thecomputing system, an indication that the computing system is unsteady.

In another aspect, an example non-transitory computer-readable medium isdisclosed. The computer-readable medium has stored thereon programinstructions that upon execution by a processor, cause performance of aset of acts including (i) capturing, by a computing system, via a cameraof the computing system, video content; (ii) encoding, by the computingsystem, the captured video content to generate a video stream; and (iii)while generating the video stream: (a) making, by the computing system,a determination that each condition in a condition set is satisfied,wherein the condition set includes a condition relating to a change in adata rate of the video stream; and (b) responsive to making thedetermination, outputting, by the computing system, via a user interfaceof the computing system, an indication that the computing system isunsteady.

In another aspect, an example computing system is disclosed. Thecomputing system is configured for performing a set of acts including(i) capturing, via a camera of the computing system, video content; (ii)encoding the captured video content to generate a video stream; and(iii) while generating the video stream: (a) making a determination thateach condition in a condition set is satisfied, wherein the conditionset includes a condition relating to a change in a data rate of thevideo stream; and (b) responsive to making the determination,outputting, via a user interface of the computing system, an indicationthat the computing system is unsteady.

In another aspect, an example method is disclosed. The method includes(i) receiving, by a first computing system, from a second computingsystem, a video stream generated by the second computing system, thevideo stream representing video content captured by the second computingsystem; and (ii) while receiving the video stream: (a) making, by thefirst computing system, a determination that each condition in acondition set is satisfied, wherein the condition set includes acondition relating to a change in a data rate of the video stream; and(b) responsive to making the determination, causing, by the firstcomputing system, the second computing system to output an indicationthat the second computing system is unsteady.

In another aspect, an example non-transitory computer-readable medium isdisclosed. The computer-readable medium has stored thereon programinstructions that upon execution by a processor, cause performance of aset of acts including (i) receiving, by a first computing system, from asecond computing system, a video stream generated by the secondcomputing system, the video stream representing video content capturedby the second computing system; and (ii) while receiving the videostream: (a) making, by the first computing system, a determination thateach condition in a condition set is satisfied, wherein the conditionset includes a condition relating to a change in a data rate of thevideo stream; and (b) responsive to making the determination, causing,by the first computing system, the second computing system to output anindication that the second computing system is unsteady.

In another aspect, an example first computing system is disclosed. Thefirst computing system is configured for performing a set of actsincluding (i) receiving, from a second computing system, a video streamgenerated by the second computing system, the video stream representingvideo content captured by the second computing system; and (ii) whilereceiving the video stream: (a) making a determination that eachcondition in a condition set is satisfied, wherein the condition setincludes a condition relating to a change in a data rate of the videostream; and (b) responsive to making the determination, causing thesecond computing system to output an indication that the secondcomputing system is unsteady.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a simplified block diagram of an example computing device.

FIG. 2 is a simplified block diagram of an example video system.

FIG. 3 is a simplified block diagram of an example video-productionsystem (VPS).

FIG. 4A is a simplified diagram of an example frame of video content,resulting from the performance of a first step in connection with adigital-video effect (DVE).

FIG. 4B is a simplified diagram of an example frame of video content,resulting from the performance of a second step in connection with theDVE.

FIG. 4C is a simplified diagram of an example frame of video content,resulting from the performance of a third step in connection with theDVE.

FIG. 4D is a simplified diagram of an example frame of video content,resulting from the performance of a fourth step in connection with theDVE.

FIG. 5A is a simplified diagram of an example frame of video content,without content overlaid thereon.

FIG. 5B is a simplified diagram of another example frame of videocontent, with content overlaid thereon.

FIG. 6 is a flow chart of an example method.

FIG. 7 is a flow chart of an example method.

DETAILED DESCRIPTION I. Overview

A VPS can generate video content that can serve as or be part of a videoprogram (e.g., a news program). The VPS can then transmit the videocontent to a video-broadcast system (VBS), which in turn can transmitthe video content to an end-user device for presentation of the videocontent to an end-user.

The VPS can include various components to facilitate generating videocontent. For example, the VPS can include a video source, a contentsystem, a first DVE system, and a second DVE system.

The video source can generate first video content, and can transmit thefirst video content to the second DVE system. In one example, the videosource can take the form of a video camera directed towards a scenewhere a news anchor is discussing a news story. Thus, in one example,the process of the video source generating the first video content caninvolve the video source capturing first video content showing the scenewhere the news anchor is discussing the news story.

The content system can transmit content, such as a set of imagesrelating to the news story, to the first DVE system. The first DVEsystem can receive the content, and can execute a DVE, which causes thefirst DVE system to generate second video content that includes thereceived content. For example, the generated second video content canshow the set of images scrolling from right to left. The first DVEsystem can then transmit the generated second video content to thesecond DVE system.

The second DVE system can receive the first video content and the secondvideo content, and can execute a DVE, which causes the DVE system tooverlay the second video content on a portion of the first videocontent, thereby generating third video content. As such, in oneexample, the third video content can include the scrolling imagesoverlaid on a portion of the scene where the news anchor is discussingthe news story. The third video content can serve as or be part of avideo program. Thus, in this way, the VPS can integrate content, such asa set of images, into a video program.

The VPS can also include a scheduling system and a sequencing system.The scheduling system can create a program schedule, perhaps based oninput received from a user (e.g., a producer or technical director) viaa user interface. The sequencing system can process records in theprogram schedule, and based on the processed records, can control one ormore components of the VPS, such as the video source, the contentsystem, the first DVE system, and the second DVE system, to facilitategenerating video content, such as in the manner described above.

The VPS can also include an end-user device that can perform variousacts and/or functions related to various types of content, perhaps basedon input received from a user (e.g., a field reporter) via a userinterface. For example, the end-user device can capture video content(e.g., video content of a newsworthy event) via a camera of the end-userdevice, and can generate and output the video content in the form of avideo stream, which the VPS can integrate into a video program.

The end-user device can generate the video stream in various ways. Forexample, the camera of the end-user device can capture the videocontent, and an encoder of the end-user device can encode (e.g.,compress) the video content to generate a video stream representing thevideo content, where the video stream can have a particular data rate(e.g., a bit rate). The video stream can be formatted into packets ofdata, which can be stored temporarily in a memory buffer of the end-userdevice before the end-user device transmits the packets from the memorybuffer to another entity, such as the content system or anothercomponent of the VPS.

In some instances, the end-user device can become unsteady while it isgenerating the video stream. For example, this can be due to the user oranother entity shaking the end-user device or otherwise causingexcessive motion of the end-user device. While the end-user device isunsteady, it can be more inefficient for the end-user device to encodethe video stream, which can lower the quality of the video stream. Tohelp account for this, the end-user device can increase the data rate ofthe video stream in an attempt achieve desirable video stream quality.

The present disclosure provides a way to help the end-user device notifythe user of the end-user device that the end-user device is unsteady, sothat the user can then reduce the motion of the end-user device. Inparticular, to facilitate this, a component of the VPS can analyze thedata rate of the video stream, use the analysis as a basis fordetermining whether the end-user device is unsteady and, if so,responsively causing the end-user device to notify the user in themanner discussed above.

In some implementations, the component that analyzes the data rate canbe the end-user device itself, which can be the device owned or operatedby the user who is capturing the video content, such as a video camerathat can be separate from or included as a component in a computingsystem (e.g., a smart phone camera). In this context, an example methodincludes the end-user device capturing video content via a camera andthen encoding the captured video content to generate a video stream. Theend-user device can capture, encode, and/or generate the video stream inthe manner discussed above, or in some other manner.

The example method also includes the end-user device, while generatingthe video stream, making a determination that each condition in acondition set is satisfied, where the condition set includes a conditionrelating to a change in a data rate of the video stream. The conditionset can include one or more conditions, such as various combinations ofthe conditions described herein.

In one example, the condition can be that the data rate of the videostream has changed by a threshold amount. To facilitate a determinationof whether this condition is satisfied, the end-user device can analyzevarious portions of the generated video stream. For instance, theend-user device can determine a first data rate for a first portion ofthe generated video stream and a second data rate for a second portionof the generated video stream, compare the two determined data rates,and determine whether the amount of change between the two determineddata rates is greater than the threshold amount. In line with thediscussion above, the end-user device determining that there has been achange in the data rate greater than the threshold amount can indicateto the end-user device that the end-user device is unsteady. Theend-user device can thus take action to notify the user of the end-userdevice that the end-user device is unsteady.

Accordingly, the example method further includes the end-user device,while generating the video stream, and responsive to making thedetermination that each condition in the condition set is satisfied,outputting, via a user interface of the end-user device, an indicationthat the end-user device is unsteady. The indication can take the formof an audio and/or visual indication, and the user interface can includevarious components through which the end-user device can output theindication, such as a sound speaker, a display device (e.g., screen),and/or a light source. In one example, the end-user device can displayto the user, on the display device of the end-user device, textindicating that the end-user device is unsteady.

In other implementations, the component that analyzes the data rate canbe the content system that is receiving the video stream transmissionfrom the end-user device. In these implementations, an example methodincludes the content system receiving, from the end-user device, a videostream generated by the end-user device. The example method alsoincludes the content system, while receiving the video stream, making adetermination that each condition in a condition set is satisfied, wherethe condition set includes a condition relating to a change in a datarate of the video stream. The condition(s) of the condition set can takevarious forms, including the example condition described above.

Further, the example method includes the content system, while receivingthe video stream, and responsive to making the determination, causingthe end-user device to output an indication that the end-user device isunsteady. There are various ways in which the content system can causethe end-user device to output the indication. In one example, thecontent system can transmit a text message to the end-user device, whichthe end-user device can then receive and display on a display device(e.g., a display screen) of the end-user device.

These features and related features are described in greater detailbelow.

II. Example Architecture

A. Computing Device

FIG. 1 is a simplified block diagram of an example computing device 100.The computing device can be configured to perform and/or can perform oneor more acts and/or functions, such as those described in thisdisclosure. The computing device 100 can include various components,such as a processor 102, a data storage unit 104, a communicationinterface 106, a user interface 108, and/or a camera system 110. Each ofthese components can be connected to each other via a connectionmechanism 112.

In this disclosure, the term “connection mechanism” means a mechanismthat facilitates communication between two or more components, devices,systems, or other entities. A connection mechanism can be a relativelysimple mechanism, such as a cable or system bus, or a relatively complexmechanism, such as a packet-based communication network (e.g., theInternet). In some instances, a connection mechanism can include anon-tangible medium (e.g., in the case where the connection iswireless).

The processor 102 can include a general-purpose processor (e.g., amicroprocessor) and/or a special-purpose processor (e.g., a digitalsignal processor (DSP)). The processor 102 can execute programinstructions included in the data storage unit 104 as discussed below.

The data storage unit 104 can include one or more volatile,non-volatile, removable, and/or non-removable storage components, suchas magnetic, optical, and/or flash storage, and/or can be integrated inwhole or in part with the processor 102. Further, the data storage unit104 can take the form of a non-transitory computer-readable storagemedium, having stored thereon program instructions (e.g., compiled ornon-compiled program logic and/or machine code) that, upon execution bythe processor 102, cause the computing device 100 to perform one or moreacts and/or functions, such as those described in this disclosure. Theseprogram instructions can define and/or be part of a discrete softwareapplication. In some instances, the computing device 100 can executeprogram instructions in response to receiving an input, such as an inputreceived via the communication interface 106 and/or the user interface108. The data storage unit 104 can also store other types of data, suchas those types described in this disclosure.

The communication interface 106 can allow the computing device 100 toconnect with and/or communicate with another entity according to one ormore protocols. In one example, the communication interface 106 can be awired interface, such as an Ethernet interface or a high-definitionserial-digital-interface (HD-SDI). In another example, the communicationinterface 106 can be a wireless interface, such as a cellular or WI-FIinterface. In this disclosure, a connection can be a direct connectionor an indirect connection, the latter being a connection that passesthrough and/or traverses one or more entities, such as a router,switcher, or other network device. Likewise, in this disclosure, atransmission can be a direct transmission or an indirect transmission.

The user interface 108 can include hardware and/or software componentsthat facilitate interaction between the computing device 100 and a userof the computing device 100, if applicable. As such, the user interface108 can include input components such as a keyboard, a keypad, a mouse,a touch-sensitive panel, and/or a microphone, and/or output componentssuch as a display device (which, for example, can be combined with atouch-sensitive panel), a sound speaker, and/or a haptic feedbacksystem.

The camera system 110 can include hardware and/or software componentsthat facilitate capturing and processing content (e.g., individualimages and/or video content). For example, the camera system 110 caninclude a camera, a frame grabber, and an encoder. The camera cancapture video content in the form of a series of images or “frames,” andcan then transmit the video content to the encoder. The frame grabbercan interface with the camera to assist in capturing the video content,such as by receiving the video content from the camera and then storingthe video content and/or transmitting the video content to the encoder.The encoder can receive the video content from the frame grabber (or, insome instances, directly from the camera), encode the video content togenerate a video stream, format the video stream into data packets, andtransmit the packets of the video stream to a memory buffer (e.g., inthe data storage unit 104), which can receive and store the packets. Theencoder can encode video content according to various standards. Forexample, the encoder can encode video content in accordance with theH.264 (MPEG-4 AVC) standard, the MPEG-2 Part 2 standard, or the VP8standard.

In some implementations, the computing device 100 can also include oneor more sensors in the form of a sensor system. For instance, the sensorsystem can include one or more motion sensors configured to measuremotion of the computing device 100, such as an accelerometer and/or agyroscope.

The computing device 100 can take various forms, such as a workstationterminal, a desktop computer, a laptop, a tablet, a mobile phone, aset-top box, and/or a television.

B. Video System

FIG. 2 is a simplified block diagram of an example video system 200. Thevideo system 200 can perform various acts and/or functions, and can beimplemented as a computing system. In this disclosure, the term“computing system” means a system that includes at least one computingdevice. In some instances, a computing system can include one or moreother computing systems.

The video system 200 can include various components, such as a VPS 202,a VBS 204, and an end-user device 206, each of which can be implementedas a computing system. The video system 200 can also include aconnection mechanism 208, which connects the VPS 202 with the VBS 204;and a connection mechanism 210, which connects the VBS 204 with theend-user device 206.

FIG. 3 is a simplified block diagram of an example VPS 202. The VPS 202can include various components, such as a video source 302, an end-userdevice 304, a content system 306, a first DVE system 308, a second DVEsystem 310, a scheduling system 312, and a sequencing system 314, eachof which can be implemented as a computing system.

The VPS 202 can also include a connection mechanism 316, which connectsthe video source 302 with the second DVE system 310; a connectionmechanism 318, which connects the end-user device 304 with the contentsystem 306; a connection mechanism 320, which connects the contentsystem 306 with the first DVE system 308; a connection mechanism 322,which connects the first DVE system 308 with the second DVE system 310;a connection mechanism 324, which connects the scheduling system 312with the sequencing system 314; a connection mechanism 326, whichconnects the sequencing system 314 with the content system 306; aconnection mechanism 328, which connects the sequencing system 314 withthe video source 302; a connection mechanism 330, which connects thesequencing system 314 with the first DVE system 308; and a connectionmechanism 332, which connects the sequencing system 314 with the secondDVE system 310.

The video source 302 can take various forms, such as a video camera, avideo server, a satellite receiver, or a DVE system. An example videoserver is the K2 server provided by Grass Valley of San Francisco,Calif.

The end-user device 304 can take various forms. In practice, the VPS 202is likely to include a large number of end-user devices 304 andcorresponding connection mechanisms, each connecting a respective one ofthe end-user devices 304 with the content system 306. The content system306 can also take various forms.

The first DVE system 308 can take various forms. An example first DVEsystem is VIZ TRIO provided by Viz Rt of Bergen, Norway. Another examplefirst DVE system is CASPAR CG provided by the Swedish BroadcastingCorporation.

The second DVE system 310 can take various forms, such as a productionswitcher. An example production switcher is VISION OCTANE provided byRoss Video Ltd. of Iroquois, Ontario in Canada.

The scheduling system 312 can take various forms. An example schedulingsystem is WO TRAFFIC provided by WideOrbit, Inc. of San Francisco,Calif. Another example scheduling system is OSI-TRAFFIC provided byHarris Corporation of Melbourne, Fla. A scheduling system is sometimesreferred to in the industry as a “traffic system.”

The sequencing system 314 can take various forms. A sequencing system issometimes referred to in the industry as a “production automationsystem.”

Referring back to FIG. 2, the VBS 204 can include various components,such as a terrestrial antenna and/or a satellite transmitter, each ofwhich can be implemented as a computing system.

Each of the video-based entities described in this disclosure caninclude or be integrated with a corresponding audio-based entity. Also,the video content described in this disclosure can include or beintegrated with corresponding audio content.

III. Example Operations

The video system 200 and/or components thereof can perform various actsand/or functions. Examples of these and related features will now bedescribed.

The video system 200 can perform various acts and/or functions relatedto video content. For example, the video system 200 can receive,generate, output, and/or transmit video content that can serve as or bepart of a video program (e.g., a news program). In this disclosure, theact of receiving, generating, outputting, and/or transmitting videocontent can occur in various ways and/or according to various standards.For example, the act of receiving, outputting, and/or transmitting videocontent can include receiving, outputting, and/or transmitting a videostream representing the video content, such as over Internet Protocol(IP) or in accordance with the high-definition serial digital interface(HD-SDI) standard. Likewise, the act of generating video content caninclude generating a video stream representing the video content. Also,the act of receiving, generating, outputting, and/or transmitting videocontent can include receiving, generating, outputting, and/ortransmitting an encoded or decoded version of the video content.

The VPS 202 can perform various acts and/or functions related to videocontent production. For example, the VPS 202 can generate and/or outputvideo content, and can transmit the video content to another entity,such as the VBS 204.

Referring again to FIG. 3, the video source 302 can generate and/oroutput video content, and can transmit the video content to anotherentity, such as the second DVE system 310. In practice, the VPS 202 islikely to include multiple video sources 302 and correspondingconnection mechanisms, each connecting a respective one of the videosources 302 with the second DVE system 310.

As noted above, in one example, the video source 302 can take the formof a video camera. In one example, the video camera can be directedtowards a scene where a news anchor is discussing a news story. Thus, inone example, the process of the video source 302 generating videocontent can involve the video source 302 capturing video content showingthe scene where the news anchor is discussing the news story.

As noted above, in another example, the video source 302 can take theform of a video server. A video server can record and/or store videocontent (e.g., in the form of a file). Further, the video server canretrieve stored video content and can use the retrieved video content togenerate and/or output a video stream representing the video content.This is sometimes referred to in the industry as the video server“playing out” the video content. The video server can then transmit thevideo stream, thereby transmitting the video content, to another entity,such as the second DVE system 310.

The end-user device 304 can perform various acts and/or functionsrelated to various types of content, perhaps based on input receivedfrom a user (e.g., a field reporter) via a user interface. For example,the end-user device 304 can capture content (e.g., an image and/or videocontent) via a camera of the end-user device 304. This can allow theend-user device 304 to capture content of a newsworthy event so that theVPS 202 can integrate the content into a video program.

The end-user device 304 can also store content in a data storage unit(e.g., a data storage unit of the end-user device 304). At a later time,the end-user device 304 can select and/or retrieve the stored content,and can transmit it to another entity, such as the content system 306.

In the case where the end-user device 304 is using a camera to capturevideo content, in one example, proximate the time that the end-userdevice 304 is capturing the content (i.e., without significant delay),the end-user device 304 can transmit the captured video content to thecontent system 306. This is sometimes referred to in the industry as a“live video transmission” or a “live video stream.” Similarly, each ofthe other entities within the VPS 202 and the VBS 204 can receivecontent and, proximate the time that the content is being received,generate, output, and/or transmit content to the next entity in thevideo production path. This can allow for live video transmissionthrough all or part of the video system 200, as desired.

In the case where the end-user device 304 uses a camera to capturecontent, the end-user device 304 can also generate metadata of thecaptured content. In one example, the end-user device 304 can generatethis metadata proximate a time that the end-user device 304 captures thecontent.

In one example, the metadata can represent a time at which the end-userdevice 304 captured at least a portion of the content. For instance, inthe case where the content is an image, the metadata can represent atime at which the end-user device 304 captured the image. Alternatively,in the case where the content is video content, the metadata canrepresent a time at which the end-user device 304 started capturing thevideo content.

In another example, the metadata can represent a location of theend-user device 304 proximate a time when the end-user device 304captured at least a portion of the content. For instance, in the casewhere the content is an image, the metadata can represent a location atwhich the end-user device 304 captured the image. Alternatively, in thecase where the content is video content, the metadata can represent alocation at which the end-user device 304 started capturing the videocontent, or a location at which the end-user device 304 captured a givenportion of the video content. In some cases, the metadata can representmultiple locations, with each location representing a location of theend-user device 304 proximate a time when the end-user device 304captured a respective portion of the video content. Metadatarepresenting a location of the end-user device 304 can take variousforms. For example, the metadata can take the form of global positioningsystem (GPS) coordinates.

The end-user device 304 can store metadata in a data storage unit (e.g.,a data storage unit of the end-user device 304), perhaps in a mannerthat associates the metadata with its corresponding content. At a latertime, the end-user device 304 can select and/or retrieve the storedcontent, and can transmit it to another entity, such as the contentsystem 306. In some examples, in the case where the end-user device 304performs an operation in connection with content, the end-user device304 can perform a parallel operation in connection with the metadata ofthat content. For example, if the end-user device 304 selects,retrieves, and transmits content to the content system 306, the end-userdevice 304 can also select, retrieve, and transmit the metadata of thecontent to the content system 306.

Like the end-user device 304, the content system 306 can perform variousacts and/or functions related to content, perhaps based on inputreceived from a user (e.g., a producer or technical director) via a userinterface. For example, the content system 306 can receive content andcan do so in various ways. In one example, the content system 306 canreceive content from another entity, such as the end-user device 304.

The content system 306 can also store, select, and/or retrieve content.As such, the content system 306 can store received content in a datastorage unit (e.g., a data storage unit of the content system 306), andcan then receive the content by selecting and retrieving it from thedata storage unit.

The content system 306 can also modify content, and can do so in variousways. Among other things, this can allow the content system 306 toremove vulgarities, personal information, and/or extraneous informationthat is not suitable or desirable for integration into a video program.

The content system 306 can also transmit content to another entity, suchas the first DVE system 308. In this disclosure, receiving andtransmitting content can include forwarding the content. Alternatively,receiving and transmitting content can include receiving the content andtransmitting a copy of the content. As such, in one example, the contentsystem 306 can receive content from the end-user device 304, and cantransmit a copy of the content to the first DVE system 308.

As with the end-user device 304, in the case where the content system306 performs an operation in connection with content, the content system306 can perform a parallel operation in connection with the metadata ofthat content. For example, the content system 306 can modify metadata byadding a unique identification number to the metadata to facilitatemanaging the corresponding content. The content system 306 can usemetadata for various reasons. For example, the content system 306 canreceive search terms and can match the search terms to metadata for thepurposes of searching for and/or selecting relevant content.

The first DVE system 308 can perform various acts and/or functionsrelated to a DVE, perhaps based on input received from a user (e.g., aproducer or technical director) via a user interface. For example, thefirst DVE system 308 can perform a set of steps based on a DVE templateto generate and/or output video content. This is sometimes referred toin the industry as “executing a DVE.”

The first DVE system 308 can create and/or modify a DVE template.Further, the first DVE system 308 can store and/or retrieve a DVEtemplate. As such, the first DVE system 308 can store a DVE template ina data storage unit (e.g., a data storage unit of the first DVE system308), and can then receive the DVE template by selecting and retrievingit from the data storage unit.

In some instances, the first DVE system 308 can use the DVE template andcontent to generate and/or output video content that includes thecontent. The first DVE system 308 can receive content to use for thispurpose in various ways. For example, the first DVE system 308 canreceive content from another entity, such as the content system 306. Inanother example, the first DVE system 308 can receive content byselecting and retrieving it from a data storage unit (e.g., a datastorage unit of the content system 306).

A DVE template can specify how the first DVE system 308 is to receivecontent. In one example, a DVE template can do so by specifying that thefirst DVE system 308 is to receive content on a particular input of thefirst DVE system 308 (e.g., an input that maps to a particular entity,such as the content system 306). In another example, a DVE template cando so by specifying that the first DVE system 308 is to receive contentby retrieving it from a particular location of a particular data storageunit (e.g., a data storage unit of the first DVE system 308).

After the first DVE system 308 generates and/or outputs video content,the first DVE system 308 can transmit the video content to anotherentity, such as the second DVE system 310, and/or can store the videocontent in a data storage unit (e.g., a data storage unit of the firstDVE system 308). As such, in one example, the first DVE system 308 canreceive content, can use the content to generate and/or output videocontent that includes the content, and can transmit the video content tothe second DVE system 310.

A DVE template can be configured in various ways and can specify variousaspects of a DVE. For example, the DVE template can specify a set ofordered steps and various timing aspects, such as when each step is tostart being performed and for how long each step is to be performed. Thesteps can relate to retrieving and/or arranging content within aspecified frame or specified frames of video content. The DVE templatecan specify that a given step is to start being performed at apredefined time, or that a given step is to start being performed at theoccurrence of, or after a time offset from the occurrence of, aparticular event, such as the conclusion of the performance of aprevious step. In another example, the occurrence of the particularevent can be the receipt of input from a user via a user interface. Inanother example, the occurrence of the particular event can be thereceipt of an instruction from the sequencing system 314.

To illustrate various aspects of a DVE, an example DVE will now bediscussed. In connection with this example, the first DVE system 308 canexecute a DVE that causes the first DVE system 308 to generate videocontent showing overlay images A, B, C, and D scrolling from right toleft over a background image. FIGS. 4A-4D are simplified depictions ofexample frames of the generated video content at various states of theDVE execution process.

During a first time period, the first DVE system 308 can perform a firststep that involves “moving” from right to left, images A and B untilimage A is positioned over a center region of the background image. FIG.4A is a simplified depiction of an example frame 400 at the end of thefirst time period.

During a next, second time period, the first DVE system 308 can performa second step that involves “moving” from right to left, images A, B,and C until image B is positioned over the center region of thebackground image. FIG. 4B is a simplified depiction of an example frame402 at the end of the second time period.

During a next, third time period, the first DVE system 308 can perform athird step that involves “moving” from right to left, images A, B, C,and D until image C is positioned over the center region of thebackground image. FIG. 4C is a simplified depiction of an example frame404 at the end of the third time period.

During a next, fourth time period, the first DVE system 308 can performa fourth step that involves “moving” from right to left, images B, C,and D until image D is positioned over the center region of thebackground image. FIG. 4D is a simplified depiction of an example frame406 at the end of the fourth time period.

As noted above, the DVE template can specify various timing aspects,such as when each step is to start being performed and for how long eachstep is to be performed. As such, in one example, the DVE template canspecify that each step is to be performed for two seconds. Further, theDVE template can specify that the first DVE system 308 is to startperforming the first step at a particular time, and that each of stepstwo, three, and four are to start being performed five seconds after theperformance of the previous step has concluded.

As such, at the start time, the first DVE system 308 can beginperforming the first step. Two seconds later, the first DVE system 308can conclude performing the first step (resulting in the generation offrame 400). Five seconds later, the first DVE system 308 can beginperforming the second step. Two seconds later, the first DVE system 308can conclude performing the second step (resulting in the generation offrame 402). Five seconds later, the first DVE system 308 can beginperforming the third step. Two seconds later, the first DVE system 308can conclude performing the third step (resulting in the generation offrame 404). Five seconds later, the first DVE system 308 can beginperforming the fourth step. Two seconds later, the first DVE system 308can conclude performing the fourth step (resulting in the generation offrame 406). Collectively, this results in the each of the images A, B,C, and D scrolling from left to right, but with each image “pausing” inthe center region for five seconds before continuing to move left.

It should be appreciated that the first DVE system 308 can execute awide variety of different types of DVEs, and can thus generate a widevariety of different types of video content. Among other things, a DVEcan involve inserting, moving, removing, overlaying, and/or scalingvarious different types of content, such as text, images, and/or videocontent, to generate resulting video content.

Like the first DVE system 308, the second DVE system 310 can performvarious acts and/or functions related to a DVE, perhaps based on inputreceived from a user (e.g., a producer or technical director) via a userinterface. For example, the second DVE system 310 can perform the actsand/or functions described above in connection with the first DVE system308, but varied as appropriate for use with the second DVE system 310instead of the first DVE system 308.

Generally, the first DVE system 308 executes certain types of DVEs, andthe second DVE system 310 executes other types of DVEs, namely thosethat are more suited to be executed further downstream in the videoproduction process. However, various DVE-related configurations arepossible. For example, either the first DVE system 308 or the second DVEsystem 310 can perform the acts and/or functions described herein asbeing performed by the other of the two systems. In another example, theVPS 202 can instead include a single DVE system that provides thefunctionality of both the first DVE system 308 and the second DVE system310.

The second DVE system 310 can receive content in various ways. Forexample, the second DVE system 310 can receive content from anotherentity, such as the video source 302 and/or the first DVE system 308. Inanother example, the second DVE system 310 can receive content byselecting and retrieving it from a data storage unit (e.g., a datastorage unit of the second DVE system 310).

The second DVE system 310 can execute a DVE based on a DVE template. TheDVE template can specify how the second DVE system 310 is to receivecontent. In one example, the DVE template can do so by specifying thatthe second DVE system 310 is to receive content on a particular input ofthe second DVE system 310 (e.g., an input that maps to a particularentity, such as the video source 302 or the first DVE system 308). Inanother example, the DVE template can do so by specifying that thesecond DVE system 310 is to receive content by retrieving it from aparticular location of a particular data storage unit (e.g., a datastorage unit of the second DVE system 310).

As noted above, a DVE template can be configured in various ways. Assuch, the second DVE system 310 can execute various types of DVEs. Inone example, a DVE template can specify that the second DVE system 310is to receive first video content from the video source 302 and secondvideo content from the first DVE system 308, and is to overlay thereceived second video content on a portion of the received first videocontent, thereby generating third video content.

FIGS. 5A and 5B help illustrate the concept of overlaying video contenton other video content. FIG. 5A is a simplified depiction of an exampleframe 500 of video content. Frame 500 shows content 502, which is ascene where a news anchor is discussing a news story, but does notinclude other content overlaid on content 502. For comparison, FIG. 5Bis a simplified depiction of another example frame 550 of video content.Frame 550 includes content 552, which is also a scene where a newsanchor is discussing a news story, but further includes other content554 overlaid on a portion of the content 552. In this example, thecontent 554 shows scrolling images related to the news story, and isoverlaid on a portion of the scene where the news anchor is discussingthe news story.

After the second DVE system 310 generates and/or outputs the videocontent, the second DVE system 310 can transmit the video content toanother entity, such as the VBS 204, and/or can store the video contentin a data storage unit (e.g., a data storage unit of the second DVEsystem 310).

As discussed above, in one example, the second DVE system 310 canreceive first video content that includes content, and can use the firstvideo content to generate and/or output second video content that alsoincludes the content. The second video content can then serve as or bepart of a video program. As such, this is an example way in which theVPS 202 can integrate content into a video program.

However, the VPS 202 can also integrate content into a video program inother ways. For example, in the case where the video source 302 is avideo camera, the first DVE system 308 can generate video content andcan transmit the generated video content to a display device locatedwithin a field of the view of the video camera. This can allow the videocamera to capture video content that includes the generated videocontent as it is displayed on the display device. Then, by integratingthe captured video content into a video program, the VPS 202 cantherefore also integrate the generated video content displayed on thedisplay device, into the video program.

In one example, the display device can be integrated with atouch-sensitive panel, which can allow a user (e.g., a news anchor) tointeract with the content. To facilitate the user's interaction with thecontent, the display device and/or related components can performparticular acts and/or functions in response to a user providing certaintouch commands.

In one example, the display device can initially display multiple smalltiles, each representing a different content item. The position andordering of the small tiles can be determined by a DVE template, whichcan specify that certain touch commands cause the display device toperform certain acts and/or functions in connection with the displayedcontent items. For example, if a user taps on one of the small items afirst time, the display device can show the content item in an enlargedview and perhaps show additional elements of, or information associatedwith, the content item. As the user interacts with the content itemsdisplayed on the display device, the video camera can generate videocontent including these interactions and thereby integrate the contentitems into the video program.

The scheduling system 312 can perform various acts and/or functionsrelated to the scheduling of video content production, perhaps based oninput received from a user (e.g., a producer or technical director) viaa user interface. For example, the scheduling system 312 can createand/or modify a program schedule. Further, the scheduling system 312 canstore and/or retrieve a program schedule. As such, the scheduling system312 can store a program schedule in a data storage unit (e.g., a datastorage unit of the scheduling system 312), and can then receive theprogram schedule by selecting and retrieving it from the data storageunit. The scheduling system 312 can also transmit a program schedule toanother entity, such as the sequencing system 314.

The sequencing system 314 can process records in the program scheduleperhaps based on input received from a user (e.g., a producer ortechnical director) via a user interface. This can cause the sequencingsystem 314 to control one or more other components of the VPS 202 tofacilitate the VPS 202 generating and/or outputting video content, whichcan serve as or be part of a video program. For example, the sequencingsystem 314 can control the video source 302, the content system 306, thefirst DVE system 308, and/or the second DVE system 310 to performvarious acts and/or functions, such as those described in thisdisclosure.

The sequencing system 314 can receive a program schedule in variousways. For example, the sequencing system 314 can do so by receiving itfrom another entity, such as the scheduling system 312. In anotherexample, the sequencing system 314 can do so by selecting and retrievingit from a data storage unit (e.g., a data storage unit of the schedulingsystem 312).

A program schedule (sometimes referred to in the industry as a“rundown”) serves as a schedule or outline of a video program and caninclude multiple records. A video program can be conceptually dividedinto multiple logically-separated portions, sometimes referred to in theindustry as “stories.” As such, each portion of the video program can berepresented by a separate record of the program schedule. In some cases,each record can also include one or more sub-records. Each record(including a sub-record) can include various types of data.

In some instances, the sequencing system 314 can process a next recordin the program schedule based on a trigger event. In one example, thetrigger event can be the sequencing system 314 completing one or moreactions related to a current record in the program schedule. In anotherexample, the trigger event can be the sequencing system 314 receivinginput from a user via a user interface.

Referring back to FIG. 2, the VBS 204 can receive video content from theVPS 202, which in turn can transmit the video content to the end-userdevice 206 for presentation of the video content to an end user. Inpractice, the video system 200 is likely to include a large number ofthese end-user devices 206 and corresponding connection mechanisms, eachconnecting the VBS 204 with a respective one of the end-user devices206. Thus, in practice, the VBS 204 can transmit video content to alarge number of end-user devices 206 for presentation of the videocontent to a large number of end users.

The VBS 204 can transmit video content to the end-user device 206 invarious ways. For example, VBS 204 can transmit video content to theend-user device 206 over-the-air or via a packet-based network such asthe Internet. The end-user device 206 can receive video content from theVBS 204, and can present the video content to an end user via a userinterface.

As discussed above, a computing system such as end-user device 304 cangenerate a video stream. For example, a camera of the end-user device304 can capture video content in the form of a series of frames, and anencoder of the end-user device 304 can encode the video content togenerate a video stream having a particular data rate. The encoder canalso format the video stream into data packets and can transmit thepackets to a memory buffer of the end-user device 304, which in turn canreceive and temporarily store the packets. The end-user device 304 canthen at some point in time (e.g., in real-time, with minimal or nodelay, while capturing the video content) transmit the packets from thememory buffer to another entity of the VPS 202, such as the contentsystem 306.

A data rate of a video stream refers to an amount of data of the videostream that is streamed per unit of time. In some instances, a data rateof a video stream can take the form of a “bit rate” of the video stream,which is the number of bits of the video stream that are streamed perunit of time, and which is quantified using units such as bits persecond (bit/s, or bps). For example, a video stream having a bit rate of500 kilobits per second (kbps) means that each second of the videostream contains 500 kilobits of data (i.e., the video stream is streamedat a rate of 500 kilobits per second).

A data rate of a video stream can affect various properties of the videostream, such as the quality (e.g., the resolution of each individualframe) and size (i.e., the amount of data required to represent thevideo stream) of the video stream, as well as the rate at which thevideo stream takes up space in the memory buffer.

As discussed above, the end-user device 304 can become unsteady while itis generating the video stream. The end-user device 304 can becomeunsteady in various ways, such as when the user or another force shakesor otherwise excessively moves the end-user device 304. The unsteadinessof the end-user device 304 can cause the camera's view of the scene tochange such that the scene captured by the camera appears in onelocation in one frame of the video content, but then appears in adifferent location in the subsequent frame of the video content.Further, because the scene can change locations between subsequentframes, at least a portion of the pixels representing the captured scenecan change locations between subsequent frames. Because video encodingtechniques involve, among other things, indicating relative changesbetween subsequent frames to reduce the data required to represent agiven video content item, video content that includes rapid motion,frequent scene changes, or other effects that cause the scene to changerapidly in time are generally less efficiently encoded. Thus,unsteadiness of end-user device 304 can make it more inefficient for theencoder of the end-user device 304 to encode the video stream, which canlower the quality of the video stream. Therefore, the end-user device304 can increase the data rate of the video stream to account for thechange in pixel locations between subsequent frames that make encodingless efficient and thereby attempt to increase the quality of the videostream (and/or maintain the quality of the video stream at apredetermined level).

To help minimize the time during which the end-user device 304 isunsteady, it can be desirable to efficiently determine that the end-userdevice 304 is unsteady and responsively notify the user of the end-userdevice 304 so that the user can steady the end-user device 304.Accordingly, the present disclosure provides methods for accomplishingthis—namely, by utilizing the data rate of the video stream generated bythe end-user device 304.

In some instances, the end-user device 304 itself can perform variousacts and/or functions relating to help determine that the end-userdevice 304 is unsteady and responsively notify the user of the end-userdevice 304. These acts and/or functions and related features will now bedescribed.

First, the end-user device 304 can capture video content and encode thevideo content to generate a video stream representing the video content,which the end-user device 304 can do in various ways as described above.

While the end-user device 304 is generating the video stream, theend-user device 304 can make a determination that each condition in acondition set is satisfied, where the condition set includes a conditionrelating to a change in a data rate of the video stream.

The condition may take a variety of forms. In one example, the conditioncan be that the data rate of the video stream has changed by a thresholdamount. To determine whether this condition has been satisfied, whilethe end-user device 304 is generating the video stream, the end-userdevice 304 can select a first portion of the video stream and a second,different portion of the video stream, determine a first data rate forthe first portion and a second data rate for the second portion, anddetermine whether an amount of change between the two determined datarates is greater than the threshold amount. If the end-user device 304determines that the change is greater than the threshold amount, theend-user device 304 can responsively then determine that the conditionis satisfied, which can indicate that the end-user device is unsteady.

In another example, the condition can be that the determined first datarate is less than a first threshold data rate and the determined seconddata rate is greater than a second threshold data rate. To determinewhether this condition has been satisfied, while the end-user device 304is generating the video stream, the end-user device 304 can select afirst portion of the video stream and a second, different portion of thevideo stream, determine a first data rate for the first portion and asecond data rate for the second portion, as discussed above. Theend-user device 304 can then compare the determined first data rate to afirst threshold data rate, and can compare the determined second datarate to a second threshold data rate. If the end-user device 304determines that the determined first data rate is less than the firstthreshold data rate and the determined second data rate is greater thanthe second threshold data rate, the end-user device 304 can responsivelythen determine that the condition is satisfied, which can indicate thatthe end-user device is unsteady.

In some aspects, the act of the end-user device 304 selecting a firstportion of the video stream and a second, different portion of the videostream can involve selecting a first time window of the video stream(e.g., three seconds of the video stream) and selecting a second,different time window of the video stream (e.g., a different threeseconds of the video stream). The first and second time windows can havethe same or different durations. For example, the first time window canbe three seconds, and the second time window can be three seconds aswell (albeit a different three second window of the video stream). Asanother example, the first time window can be three seconds, and thesecond time window can be six seconds.

In other aspects, the act of the end-user device 304 selecting a firstportion of the video stream and a second, different portion of the videostream can involve selecting a first series of frames of the videostream and selecting a second, different series of frames of the videostream. The first series of frames and the second, different series offrames can each include the same quantity of frames or a differentquantity of frames. For example, the first series of frames can includeninety frames, and the second series of frames can include ninety framesas well (albeit a different sequence of ninety frames of the videostream). As another example, the first series of frames can includeninety frames, and the second series of frames can include one hundredand twenty frames.

The act of the end-user device 304 selecting a first portion of thevideo stream and a second, different portion of the video stream caninvolve selecting the first portion and the second portion such that thetwo portions include a common portion of the video stream. To illustratethis, consider an example scenario in which the video stream includesone hundred and twenty frames. In this scenario, the end-user device 304can select a first portion of the video stream that includes a firstseries of frames, shift over to a different portion of the video streamby a certain amount, and then select a second portion of the videostream that includes a second series of frames. For instance, theend-user device 304 can select a first portion of the video stream thatincludes frames one through ninety, shift over by thirty frames, andthen select a second portion of the video stream that includes framesthirty-one through one hundred and twenty. As such, both the firstportion and the second portion include a common portion of framesthirty-one to ninety.

Further, consider for example, in this scenario, that the condition isthat the determined first data rate is less than a first threshold datarate and the determined second data rate is greater than a secondthreshold data rate. In view of this, the end-user device 304 candetermine a first data rate for frames one through ninety (i.e., theamount of data per second of the first series of ninety frames), anddetermine a second data rate for frames thirty-one through one hundredand twenty (i.e., the amount of data per second of the second series ofninety frames). The end-user device 304 can then determine whether thecondition is satisfied in one or more of the manners discussed above.

In some aspects, the act of the end-user device 304 determining whetherthe condition relating to a change in a data rate of the video stream issatisfied can involve the end-user device 304 selecting more than twoportions of the video stream, determining respective data rates for eachportion, and then determining whether the condition has been satisfiedin one or more of the manners discussed above.

The end-user device 304 can select the thresholds discussed above invarious ways. For instance, the end-user device 304 can select thethresholds based on the encoding standard used by the encoder forgenerating the video stream. As an example, consider the scenariodiscussed above in which the end-user device 304 compares the first datarate of the first portion to a first threshold and compares the seconddata rate of the second portion to a second threshold. In this scenario,if the end-user device 304 determines that the encoder is using theH.264 encoding standard, the end-user device 304 can responsively use afirst threshold data rate having a value in a range of 300 kbps to 400kbps (e.g., 350 kbps), and use a second threshold data rate having avalue in a range of 600 kbps to 700 kbps (e.g., 650 kbps). As anotherexample, consider the scenario discussed above in which the end-userdevice 304 determines whether the change in the data rate is at least athreshold amount. In this scenario, if the end-user device 304determines that the encoder is using the H.264 encoding standard, theend-user device 304 can responsively use a threshold amount having avalue in a range of 250 kbps to 350 kbps (e.g., 300 kbps). Otherexamples are possible as well, and other thresholds discussed herein canbe predefined or selected in a similar manner.

As noted above, the first portion of the video stream and the second,different portion of the video stream can take the form of a firstseries of frames and a second, different series of frames, eachincluding the same quantity of frames. In some aspects, the end-userdevice 304 can select the quantity of frames for the first and secondportions based on the encoding standard. As an example, if the end-userdevice 304 determines that the encoder is using the H.264 encodingstandard, the end-user device 304 can responsively select the quantityof frames to be a value in a range of 80 frames to 100 frames (e.g., 90frames), such that the first and second portions each include thequantity of frames. The end-user device 304 can select the quantity offrames in other manners as well.

The condition set can include other conditions as well, additionally oralternatively to the condition relating to a change in a data rate ofthe video stream. In some aspects, the end-user device 304 can includeone or more sensors configured to measure motion of the end-user device304, such as an accelerometer configured to measure accelerationinvolved in the motion of the end-user device 304, or a gyroscopeconfigured to measure the orientation of the end-user device 304, asnoted above. As the end-user device 304 moves unsteadily, theacceleration and/or orientation data obtained via one or more of thesesensors can change. The end-user device 304 can thus monitor thesechanges to help determine whether the end-user device 304 is unsteady.

As such, the condition set can include a condition relating to data(i.e., measurements) obtained via one or more of these sensors. Forinstance, the condition set can include a condition relating toaccelerometer data obtained via the accelerometer of the end-user device304. In one example, the condition can be that the determinedaccelerometer data (e.g., an indication of the magnitude of theacceleration of the end-user device 304 over a given time period) is atleast a threshold value. If the end-user device 304 determines that theaccelerometer data is at least the threshold value, the end-user device304 can determine that the condition is satisfied, which can indicatethat the end-user device is unsteady.

In another example, the condition can relate to a change in theaccelerometer data. To facilitate this, the end-user device 304 candetermine first accelerometer data from a first point in time during theend-user device's motion and determine second accelerometer data from asecond point in time during the end-user device's motion. The first andsecond points in time can be close together (e.g., one second apart orless) or far apart (e.g., greater than one second apart). In one aspect,the end-user device 304 can then compare the determined data todetermine whether a change from the first accelerometer data to thesecond accelerometer data is at least a threshold amount. In thisaspect, if the end-user device 304 determines that the change is atleast a threshold amount, the end-user device 304 can determine that thecondition is satisfied, which can indicate that the end-user device isunsteady.

Alternatively, in another aspect, the end-user device 304 can comparethe first accelerometer data to a first threshold and can compare thesecond accelerometer data to a second threshold. In this aspect, if theend-user device 304 determines that the first accelerometer data is lessthan the first threshold and determines that the second accelerometerdata is greater than the second threshold, the end-user device 304 candetermine that the condition is satisfied, which can indicate that theend-user device is unsteady.

Other examples of conditions relating to sensor data are possible aswell, such as comparing gyroscope data (e.g., an indication of theextent of change in orientation of the end-user device 304 over a giventime period) to one or more thresholds similar to the approach outlinedfor accelerometer data above.

As discussed above, in response to the end-user device 304 making thedetermination that each condition in the condition set is satisfied, theend-user device 304 can output, via a user interface of the end-userdevice 304 (e.g., user interface 108), an indication that the end-userdevice 304 is unsteady. The user interface of the end-user device 304can include various components through which the end-user device 304 canoutput the indication, such as a sound speaker, a display device, and/ora light source other than the display device (e.g., a light-emittingdiode (LED) light source integrated with the end-user device's camera).

The indication can take various forms, such as an audio indication, avisual indication, or a combination of an audio and visual indication.In one example, the indication can be one or more tones (e.g., beeps)played out of the sound speaker of the end-user device 304, each tonehaving a particular pitch and volume suitable for alerting the user ofthe end-user device 304. In another example, the indication can be alight flashed a single time or repeatedly by the light source of theend-user device 304. In another example, the indication can be a messagedisplayed on the display device of the end-user device 304. Forinstance, the message can include text stating “The device is unsteady”and/or “Hold the device steady.” Other examples are possible as well.

In some aspects, while generating the video stream, the end-user device304 can use the display device to display a preview of the video contentthat is being generated and streamed in the form of the video stream. Inparticular, the display device can act as a preview window, and theend-user device 304 can display the video content in the preview window.In these aspects, the act of the end-user device 304 outputting theindication can involve displaying the indication in the preview windowsuch that the indication is overlaid on the video content. This canallow the end-user device 304 to notify the user that the end-userdevice 304 is unsteady while the user is watching the preview of thevideo content in the preview window.

In some aspects, the act of the end-user device 304 outputting theindication can involve outputting the indication for a predefined timeperiod. The predefined time period can begin immediately once theend-user device 304 determines that each condition of the condition setis satisfied, or the predefined time period can begin at a later time.In these aspects, the end-user device 304 can then at some point make adetermination that the predefined time period has elapsed and, inresponse to making the determination that the predefined time period haselapsed, the end-user device 304 can remove the indication. For example,the act of the end-user device 304 removing the indication can involvethe end-user device 304 causing the light source to stop flashing alight, causing the display device to stop displaying a message, and/orcausing the sound speaker to stop playing a tone. Other examples arepossible as well.

In variations of these aspects, the act of the end-user device 304outputting the indication for the predefined time period can involveoutputting the indication intermittently or continuously throughout theduration of the predefined time period. For example, the end-user device304 can flash a light every half second during the time period until thetime period has elapsed. Other examples are possible as well.

In other instances, the content system 306 can perform various actsand/or functions to help determine that the end-user device 304 isunsteady and can responsively notify the user of the end-user device304. These acts and/or functions and related features will now bedescribed.

First, the content system 306 can receive the video stream generated bythe end-user device 304. While the content system 306 is receiving thevideo stream, the content system 306 can make a determination that eachcondition in a condition set is satisfied, where the condition setincludes a condition relating to a change in a data rate of the videostream.

The content system 306 can perform various acts to make thedetermination, such as the acts described above with regard to theend-user device 304. The content system 306 can select variousthresholds for use in making the determination, such as those discussedabove, and can determine which thresholds to use in a similar manner asthe end-user device 304. For example, the content system 306 candetermine which encoding parameters the end-user device 304 is using,and use that determination as a basis for selecting certain thresholds.The content system 306 can determine the encoding parameters in variousways. For instance, the end-user device 304 can notify the contentsystem 306 of which encoding parameters the end-user device 304 isusing, the content system 306 can analyze the video stream to determinethe encoding parameters, or the content system 306 can learn of theencoding parameters the end-user device 304 from another entity otherthan the end-user device 304.

Further, in response to the content system 306 making the determinationthat each condition in the condition set is satisfied, the contentsystem 306 can cause the end-user device 304 to output an indicationthat the end-user device 304 is unsteady. The indication can take one ormore of the forms described above.

In some aspects, the act of the content system 306 causing the end-userdevice 304 to output the indication can involve transmitting, to theend-user device 304, an instruction to output the indication. In turn,while the end-user device 304 is generating the video stream, theend-user device 304 can receive the instruction and can responsivelythen output the indication. In other aspects, the act of the contentsystem 306 causing the end-user device 304 to output the indication caninvolve transmitting, to the end-user device 304, a message including avisual indication that the end-user device 304 is unsteady, such as atext message via a Short Message Service (SMS). In turn, while theend-user device 304 is generating the video stream, the end-user device304 can receive the message, and can responsively then display themessage (or can display an alert to the user that the message has beenreceived).

Additionally or alternatively to the content system 306 causing theend-user device 304 to output the indication, the content system 306 canitself output, via a user interface of the content system 306, anindication that the end-user device 304 is unstable, such as one or moreof the indications described above. This can allow a user of the contentsystem 306 to notify a user of the end-user device 304 to stabilize theend-user device 304.

FIG. 6 is a flow chart illustrating an example method 600. In an exampleimplementation, a computing system such as the end-user device 304 canperform the method 600.

At block 602, the method 600 can include capturing, via a camera of thecomputing system, video content.

At block 604, the method 600 can include encoding the captured videocontent to generate a video stream.

At block 606, the method 600 can include, while generating the videostream: (i) making a determination that each condition in a conditionset is satisfied, where the condition set includes a condition relatingto a change in a data rate of the video stream, and (ii) responsive tomaking the determination, outputting, via a user interface of thecomputing system, an indication that the computing system is unsteady.

FIG. 7 is a flow chart illustrating another example method 700. In anexample implementation, a first computing system such as the contentsystem 306 can perform the method 700.

At block 702, the method 700 can include receiving, from a secondcomputing system, a video stream generated by the second computingsystem, the video stream representing video content captured by thesecond computing system.

At block 704, the method 700 can include, while receiving the videostream: (i) making a determination that each condition in a conditionset is satisfied, where the condition set includes a condition relatingto a change in a data rate of the video stream, and (ii) responsive tomaking the determination, causing the second computing system to outputan indication that the second computing system is unsteady.

IV. Example Variations

Although some of the acts and/or functions described in this disclosurehave been described as being performed by a particular entity, the actsand/or functions can be performed by any entity, such as those entitiesdescribed in this disclosure. Further, although the acts and/orfunctions have been recited in a particular order, the acts and/orfunctions need not be performed in the order recited. However, in someinstances, it can be desired to perform the acts and/or functions in theorder recited. Further, each of the acts and/or functions can beperformed responsive to one or more of the other acts and/or functions.Also, not all of the acts and/or functions need to be performed toachieve one or more of the benefits provided by this disclosure, andtherefore not all of the acts and/or functions are required.

Although certain variations have been discussed in connection with oneor more examples of this disclosure, these variations can also beapplied to all of the other examples of this disclosure as well.

Although select examples of this disclosure have been described,alterations and permutations of these examples will be apparent to thoseof ordinary skill in the art. Other changes, substitutions, and/oralterations are also possible without departing from the invention inits broader aspects as set forth in the following claims.

What is claimed is:
 1. A method comprising: receiving, by a computingsystem, from an end-user device, a video stream generated by theend-user device, the video stream representing video content captured bya camera of the end-user device, wherein the video stream has a datarate, wherein the data rate is an amount of data of the video streamthat is streamed per unit of time; and while receiving the video stream:making, by the computing system, a determination that each condition inthe condition set is satisfied, wherein the condition set includes acondition relating to a change in the data rate of the video stream withrespect to at least one threshold; and responsive to making thedetermination, causing, by the computing system, the end-user device tooutput, via a user interface of the end-user device, an indication thatthe end-user device is unsteady.
 2. The method of claim 1, furthercomprising: while receiving the video stream: determining, by thecomputing system, one or more encoding parameters being used by theend-user device to generate the video stream; and based on thedetermined one or more encoding parameters, selecting, by the computingsystem, the at least one threshold for use in making the determinationthat each condition in the condition set is satisfied.
 3. The method ofclaim 2, wherein the determined one or more encoding parameters includesan encoding standard being used by the end-user device to generate thevideo stream.
 4. The method of claim 1, wherein the computing system isa content system of a video production system (VPS), wherein the VPS isconfigured to integrate the video stream into a video program forproduction.
 5. The method of claim 1, wherein causing the end-userdevice to output the indication comprises transmitting, to the end-userdevice, an instruction to output the indication, the method furthercomprising: while the end-user device is generating the video stream:receiving, by the end-user device, from the computing system, theinstruction; and responsive to receiving the instruction, outputting, bythe end-user device, via the user interface of the end-user device, theindication.
 6. The method of claim 1, wherein the indication is a visualindication, and wherein causing the end-user device to output theindication comprises transmitting, to the end-user device, a messageincluding the visual indication, the method further comprising: whilethe end-user device is generating the video stream: receiving, by theend-user device, from the computing system, the message including thevisual indication; and responsive to receiving the message including thevisual indication, displaying, by the end-user device, via the userinterface of the end-user device, the message.
 7. The method of claim 1,wherein the at least one threshold includes a threshold amount, andwherein the condition is that the change in the data rate of the videostream is at least the threshold amount.
 8. The method of claim 1,wherein the generated video stream includes a first portion and a secondportion that is different from the first portion, the method furthercomprising: while generating the video stream, determining, by thecomputing system, a first data rate of the first portion and a seconddata rate of the second portion, wherein the at least one thresholdincludes a first threshold data rate and a second threshold data rate,and wherein the condition is that the determined first data rate is lessthan the first threshold data rate and the determined second data rateis greater than the second threshold data rate.
 9. The method of claim8, wherein each of the first and second portions of the generated videostream include a common portion of the generated video stream.
 10. Anon-transitory computer-readable medium having stored thereon programinstructions that upon execution by a processor, cause performance of aset of acts comprising: receiving, by a computing system, from anend-user device, a video stream generated by the end-user device, thevideo stream representing video content captured by a camera of theend-user device, wherein the video stream has a data rate, wherein thedata rate is an amount of data of the video stream that is streamed perunit of time; and while receiving the video stream: making, by thecomputing system, a determination that each condition in the conditionset is satisfied, wherein the condition set includes a conditionrelating to a change in the data rate of the video stream with respectto at least one threshold; and responsive to making the determination,causing, by the computing system, the end-user device to output, via auser interface of the end-user device, an indication that the end-userdevice is unsteady.
 11. The non-transitory computer-readable medium ofclaim 10, the set of acts further comprising: while receiving the videostream: determining, by the computing system, one or more encodingparameters being used by the end-user device to generate the videostream; and based on the determined one or more encoding parameters,selecting, by the computing system, the at least one threshold for usein making the determination that each condition in the condition set issatisfied.
 12. The non-transitory computer-readable medium of claim 11,wherein the determined one or more encoding parameters includes anencoding standard being used by the end-user device to generate thevideo stream.
 13. The non-transitory computer-readable medium of claim10, wherein the computing system is a content system of a videoproduction system (VPS), wherein the VPS is configured to integrate thevideo stream into a video program for production.
 14. The non-transitorycomputer-readable medium of claim 10, wherein causing the end-userdevice to output the indication comprises transmitting, to the end-userdevice, an instruction to output the indication, the set of acts furthercomprising: while the end-user device is generating the video stream:receiving, by the end-user device, from the computing system, theinstruction; and responsive to receiving the instruction, outputting, bythe end-user device, via the user interface of the end-user device, theindication.
 15. The non-transitory computer-readable medium of claim 10,wherein the indication is a visual indication, and wherein causing theend-user device to output the indication comprises transmitting, to theend-user device, a message including the visual indication, the set ofacts further comprising: while the end-user device is generating thevideo stream: receiving, by the end-user device, from the computingsystem, the message including the visual indication; and responsive toreceiving the message including the visual indication, displaying, bythe end-user device, via the user interface of the end-user device, themessage.
 16. The non-transitory computer-readable medium of claim 10,wherein the at least one threshold includes a threshold amount, andwherein the condition is that the change in the data rate of the videostream is at least the threshold amount.
 17. The non-transitorycomputer-readable medium of claim 10, wherein the generated video streamincludes a first portion and a second portion that is different from thefirst portion, the set of acts further comprising: while generating thevideo stream, determining, by the computing system, a first data rate ofthe first portion and a second data rate of the second portion, whereinthe at least one threshold includes a first threshold data rate and asecond threshold data rate, and wherein the condition is that thedetermined first data rate is less than the first threshold data rateand the determined second data rate is greater than the second thresholddata rate.
 18. The non-transitory computer-readable medium of claim 17,wherein each of the first and second portions of the generated videostream include a common portion of the generated video stream.
 19. Acomputing system comprising: a communication interface, wherein thecomputing system is configured for performing a set of acts comprising:receiving, from an end-user device, a video stream generated by theend-user device, the video stream representing video content captured bya camera of the end-user device, wherein the video stream has a datarate, wherein the data rate is an amount of data of the video streamthat is streamed per unit of time; and while receiving the video stream:making a determination that each condition in the condition set issatisfied, wherein the condition set includes a condition relating to achange in the data rate of the video stream with respect to at least onethreshold; and responsive to making the determination, causing theend-user device to output, via a user interface of the end-user device,an indication that the end-user device is unsteady.
 20. The computingsystem of claim 19, wherein the computing system is a content system ofa video production system (VPS), wherein the VPS is configured tointegrate the video stream into a video program for production.